Post on 18-Apr-2021
Stretch Efficiency – Thermodynamic Analysis of New Combustion Regimes
(Agreement 10037) C. Stuart Daw, Josh A. Pihl, A. Lou Qualls,
V. Kalyana Chakravarthy, Johney B. Green, Jr., Ronald L. Graves (PI)
Fuels, Engines, and Emissions Research Center Oak Ridge National Laboratory
2008 DOE OVT Merit Review Bethesda, MD
Februay 26, 2008
Gurpreet Singh, Steve Goguen Vehicle Technologies U.S. Department of Energy
Managed by UT-Battelle for the Department of Energy This presentation does not contain any proprietary or confidential information
Purpose: reduce petroleum consumption by improving fuel efficiency
• Summarize understanding of ICE efficiency losses
• Identify promising strategies to reduce losses
• Implement proof-of-principle demonstrations of selected concepts
• Novel approach within OVT portfolio: focused on long term, high risk approaches for reducing fundamental thermodynamic losses in combustion
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Today’s engines
LossesFuel 58-60%Efficiency
40-42%
Fuel Losses Efficiency 40-50%
50-60%
Tomorrow’s engines?
Activity addresses multiple barriers to high efficiency ICEs
• FCVT MYPP Technical Challenges & Barriers – "Engine efficiency improvement...and minimization
of engine technology development risk are inhibited by inadequate understanding of…thermodynamic combustion losses..."
• 21st Century Truck Partnership Roadmap Barriers to Achieving Efficiency Goals
– “Relatively large thermodynamic losses in traditional combustion processes.”
• FreedomCAR ACEC Tech Team Roadmap Barriers to Thermal Efficiency Goals
– “Inherent exergy losses in conventional combustion processes. Among the largest losses in internal combustion engines, the availability destruction in rapid flame propagation may be only offset to a limited extent by LTC modes.“
– "Inadequate baseline for energy balance and availability (exergy) losses…. Understanding the losses is key...for achieving higher efficiency."
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No guidance received from previous reviews
• FY05-06: Project funding too small for formal review
• FY07: Project presented on a poster – Only scored by one reviewer – No reviewer comments given
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Approach incorporates thermodynamic analyses of ICE losses, demonstration of mitigation strategies, and concepts for ICE implementation • Phase I: Assembled team of expert collaborators to help clarify
theoretical ICE efficiency limits based on literature and selected case studies – Identified most promising paths forward – Recommended specific topic areas for follow-on study
• Phase II: Develop and implement an experimental study to demonstrate more efficient combustion – Target: Reduce by half the 20-25% fuel efficiency loss in current engines
due to combustion irreversibility – Intended to be proof-of-principle
• Phase III: Develop a concept for implementation of strategies from Phase II on an ICE – Intended to lead to practical application
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Phase I work focused on analysis of combustion losses and strategies to reduce those losses • Revisited constraints on efficiency with collaborators
– Ben Druecke, Dave Foster, Sandy Klein, University of Wisconsin-Madison
– Jerry Caton, Pramod Chavannavar, Texas A&M Univ.
• Consulted other widely recognized experts – John Clarke, Caterpillar, retired – Noam Lior, University of Pennsylvania – John Farrell and Walt Weissman, Exxon Mobil – Chris Edwards, Stanford University/GCEP
• Addressed following issues: – Identification and quantification of current inefficiencies – Clarification of physical constraints from 1st and 2nd laws – Identification of approaches to counteract inefficiencies
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1 2
Largest losses: wall heat transfer, unrecoveredexhaust energy, and combustion irreversibility• Availability = energy Octane-fueled spark-ignition engine
available to produce work (exergy)– HC fuel availability ≈
heating value
• Wall heat transfer depends on materials and combustion details
• Utilizing exhaust availability requires cycle compounding
• Reducing combustion irreversibility requires fundamental changes to Energy Availability
the combustion process (1st Law) (2nd Law)
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(J. Caton, 1999)
ENER
GY
or A
VAIL
AB
ILIT
Y (%
)
0
20
40
60
80
100
(30.6%)
(28.7%)
(40.0%)
Destruction due to
Combustion (20.6%)
Unused Fuel
(0.7%)
(24.7%)
(23.0%)
(29.7%)
Unused Fuel
(0.7%)
Destruction due to
Inlet Mixing(1.3%)
Total Indicated
Work
Heat Transfer
Net Transfer Out Due to Flows
Combustion irreversibility is the least understood of the major losses
H2 flame front • Irreversibility is caused by Tcool Tmax Tadiabatic combustion reactions occurring
far from chemical & thermal equilibrium (unrestrained chemical reactions)
• Molecular-scale gradients result in entropy generation,* reducing availability
– internal heat transfer – molecular rearrangements – gradients in chemical potential
• Lost availability can never be recovered (2nd law)
*See W. R. Dunbar and N. Lior, Sources of Combustion Irreversibility, 8 Managed by UT-Battelle
for the Department of Energy Combustion Science and Technology, Vol 103, 1994.
C.S. Daw, V.K. Chakravarthy, J. Conklin, and R.L. Graves, Intl. J. of H2 Energy 31 (2006) 728-736
Combustion irreversibility is unchanged for HCCI and HCCI-like modes • Comparison of conventional
and HCCI H2 combustion in adiabatic engine
• Even with homogeneous combustion (no macroscopic spatial gradients), irreversibility substantial
• Reactions still occurring far from chemical & thermal equilibrium (unrestrained)
• Entropy generation and availability loss effectively unchanged
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Exhaust availability
Piston work
Combustion irreversibility
(HCCI) (flame)
V. Chakravarthy, C.S. Daw, R. Graves, B. Druecke, D. Foster, S. Klein, “Second Law Comparison of Volumetric and Flame Combustion in an Ideal Engine with Exhaust Heat Recovery,” Proc. Of Tech. Mtg of Central States Section of Combustion Inst., May 2006
Combustion irreversibility minimized by stoich. fueling, but at expense of reduced expansion work • Combustion irreversibility 1
reduced for stoichiometric
thermal exhaust
availability
ideal gas expansion work
total post-combustion availability
irreversibilityequivalance ratio– reactions still unrestrained
but with fewer molecules
Frac
tion
of O
rigin
al F
uel E
nerg
y 0.9
– less dilution of reaction 0.8
products – lower entropy generation
0.7
• Effect masked in traditional ICEs by reduced expansion work extraction for 0.6
stoichiometric mixture
• Recovering higheravailability fromstoichiometric combustion will require cyclecompounding
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0.5 0.4 0.5 0.6 0.7 0.8 0.9
Fuel-to-Air Equivalence Ratio
Plot details: • ideal adiabatic combustion of iso-octane
and air • fully expanded otto cycle with initial
compression ratio = 10
1
Most promising paths to higher efficiency identified
Lower impact paths: Higher impact paths:
• HCCI, except as it: • Staged combustion, with near-– reduces heat losses equilibrium reactions – enables stoich. combustion • Stoichiometric combustion
• Lean-burn • Reduced wall heat transfer • Matching reaction rates to work • Cycle compounding, especially
extraction with exhaust heat recovery • CR>10
Other observations:
• Most opportunities for incremental improvements have already been pursued
• Large improvements will require globally integrated systems perspective (simultaneous optimization of combustion, heat transfer, work extraction)
• Optimized combustion engines are likely to be very different from today's single-stage piston engines
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Phase II focused on demonstrating reduced combustion irreversibility • Target: Demonstrate a reduction of the fuel availability loss due
to combustion irreversibility from ~20% to ~10% in a bench-top constant pressure combustor
• Strategy: Utilize techniques to restrain or stage the combustion process and carry out the reactions closer to equilibrium – CPER (Counterflow Preheating with near-Equilibrium Reaction)
• idealized process for carrying out combustion in near-equilibrium fashion – fuel and air equilibrated at high temperature prior to mixing,
minimizing “internal” heat transfer – heating of reactant streams by exhaust gas accomplished in
counterflow preheaters to minimize temperature gradients – gas flows undergo reaction inside preheaters
• difficult to achieve in idealized form due to high temperatures involved
– TCR (Thermo-Chemical Recuperation) • utilizes exhaust heat to drive endothermic reforming reactions over an
appropriate catalyst • stages the combustion process, enabling (partial) near-equilibrium
reaction at much lower temperatures than CPER alone 12 Managed by UT-Battelle
for the Department of Energy
Conceptual schematic of CPER-TCR combustor
Combustion Chamber
Reformate/Air Super-Adiabatic Mixing and
Reaction Exhaust
Reformer/Heat Exchanger Global availability CV
• Combustion process redistributed into stages: – Air preheated with counterflow exhaust (thermal recuperation) – Fuel reformed and preheated with counterflow exhaust (thermo-
chemical recuperation)
• Near equilibrium reforming and small ΔT heat transfer reduce entropy and increase output availability, generating super-adiabatic exhaust
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Air PreheaterAir (300K)
Cool Exhaust
Preheated Air
Hot Exhaust Heat Exchanger
Fuel Preheater
Fuel + H2O (300K)
Cool Exhaust
Preheated Reformate
Hot Exhaust
Design for demonstration of reduced combustion irreversibility with CPER-TCR • Exhaust exits top of burner
chamber via three separate vents
• Valves on vent lines allow control of flow rates through exhaust manifold components
• Incoming fuel and air preheated by exhaust in counterflow heat exchangers
• Fuel can be mixed with water vapor and steam reformed in catalyst chamber
• Instrumented with thermocouples and gas flow meters to measure exhaust energy flows
• Two quartz windows provide optical access to burner
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Exhaust
Inlet Fuel Inlet Air
Fuel Preheater
Catalyst Chamber
Quartz Window
Burner
Preheated Fuel
Preheated
Air Preheater
Air
Combustor incorporates counterflow preheaters for air and fuel and reformer catalyst on fuel inlet
fuel preheater/reformer
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air preheater
Construction of combustor has been completed
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Shake-down experiments are underway
burner assembly fully assembled with preheaters combustor
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Technology transfer achieved through industrial collaborations, presentations, publications
• Consulted with industry representatives during Phase I analyses.
• Published and presented Phase I conclusions.
• Identified catalyst supplier interested in TCR application and willing to provide catalyst samples.
• Negotiating NDA with industrial partner interested in collaborating on, and possibly commercializing, CPER-TCR.
• Will publish/present Phase II results.
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Future work focused on CPER-TCR demonstration and application in ICEs • Remainder of FY08
– Complete combustor shakedown – Conduct experiments & analyses to quantify availability in CPER-TCR
combustor • with varying degrees of fuel and air preheating • with and without reforming
• FY09 and beyond – Refine CPER/TCR for application in ICEs – Analyze preheating and reforming pre/post compression – Consider approaches for converting recovered chemical energy to
pressure versus heat – Design, construct, and control preheater/reactors to minimize thermal
gradients and maximize conversion – Define theoretical impacts of compounding with other work extraction
cycles (e.g., topping and bottoming cycles, integration with turbo-charging, thermo-electrics)
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Summary • Relevance to DOE Objectives
– Identifying pathways to reduced petroleum consumption through improved combustion engine efficiency
– Supporting DOE-OVT needs for improved fundamental knowledge of engine combustion and efficiency related to thermodynamic losses
• Approach – Conduct proof-of-principle demonstration of staged/restrained combustion
techniques that reduce availability losses due to combustion irreversibility
• Technical Accomplishments – Completed construction of constant pressure bench-top CPER-TCR combustor
• Technology Transfer – Publishing and presenting results in relevant forums – Pursuing collaboration with industrial partner
• Future Plans – Conduct experiments with CPER-TCR combustor to demonstrate reduced
availability losses – Refine CPER/TCR strategies for use in ICEs
20 Managed by UT-Battellefor the Department of Energy